Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
CA 02301971 2000-03-22
Mach-Zhender interferometer (MZI) filter devices
Inventors : Jaedong Park, Ken Hongkeun Cho, and Hamid Hatami-Hanza
1. Field of invention
This invention generally relates to optical filters and in particular cascaded
Mach-
Zhender Interferometers. Each MZI has different length between each arm and
filters
desired channels at different output ports.
2. Introduction
Optical filters are desirable in modern optical communication transmission
systems and networks. These optical systems and networks use Wavelength
Division Multiplexed (WDM) signals, in which each dada channel sends its data
using a light signal with a particular wavelength. WDM signaling increases the
transmission capacity while providing more flexibility by the possibility of
wavelength connectivity, routing, etc. Optical filters that can combine or
separate
different wavelength channels, known as WDM multiplexers and demultiplexers,
therefore are important components of these systems. WDM filters can be
fabricated by variety of methods such as using thin film dielectric filters or
array
waveguide gratings utilizing planar optical waveguides. WDM filters also can
be
made by interferometers and more specifically by number of interferometers
cascaded in a pre arranged configurations. One class of these interferometer
based
optical filters are Cascaded Asymmetric Mach-Zhender Interferometers (MZIs).
Asymmetric MZIs show a periodic response as a function of wavelength the
period of which is a function of length difference between the arms of the
interferometer. The longer the length difference the shorter the wavelength
response oscillations and therefore the higher wavelength selectivity.
Asymmetric
MZIs once are connected to each other as interleaver can multiplex or
demultiplex
a large number of optical signals with different wavelengths such as the
standard
CA 02301971 2000-03-22
ITU grid wavelengths. An optical filter interleaves can separate the odd and
even
wavelengths from a WDM signal with a number of wavelengths.
The MZIs that are constructed by optical fibers are called all fiber MZIs. All
fiber
MZIs are desirable because of their excellent compatibility with the
transmission
media; i.e. optical fibers, and low polarization dependency and low insertion
loss
compaFed to other WDM filters fabricated by other technologies. However the
challenge in all fiber Asymmetric MZIs is to control the length difference
between the arms of an all fiber asymmetric MZI since the wavelength response
depends on this length dii~erence. To make an all fiber MZI, two optical
couplers
that are used as splitter and combines in the interferometers are fabricated
in the
predetermined positions. The optical couplers in an all fiber MZI
configuration
are usually fused tapered couplers. In fabricating fused tapered couplers two
optical fibers are brought into close proximity and are heated to certain
degree
while pulling the two fibers so that the cores of the optical fibers come
close
enough to each other so much so they can start to transfer energy by
evanescent
field coupling.
The processes of making fused tapered couplers are relatively sensitive and
have a
low yield to achieve a desired coupling, i.e. splitting, ratio. However making
two
optical fused coupler in an asymmetric interferometer configuration with
accurate
length differences in one process will be even more challenging making all
fiber
asymmetric MZIs a low yield process.
It is therefore desirable to have an alternative and lower cost method of
constructing all fiber asymmetric MZIs.
3. Summary of the invention
In order to construct an all fiber asymmetric MZI we first start with a
coupler with
two arms in the form of a Michelson interferometer. Then we adjust the lengths
of the
arms of Michelson interferometer by precision grinding and polishing until
achieving
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CA 02301971 2000-03-22
the desired wavelength response from the Michelson interferometer. While doing
that
we will also have a very accurate estimate of the length difference between
the arms
of the Michelson interferometer from the analytical relations between the
length
difference and the wavelength response. It is also possible to measure the
length
difference between the two arms of the Michelson interferometer by high
precision
reflectometers such as HP model No 8504B with a resolution of better than 20
micron. To-achieve even a better resolution than using the mentioned
reflectometer
we can also use optical spectrum analyzers to compute the length difference
from the
spectral shape of the Michelson interferometer wavelength response. By the
latter
method we can adjust the length difference within a micron precision.
After having the Michelson interferometers with the desired length difference
we can
then construct a Mach-Zhender Interferometer by connecting two Michelson
interferometers back to back. The total length difference of the asymmetric
MZI
therefore is either the sum of the length differences of the two individual
Michelson
interferometers or the difference of the two. In this way we can have a
systematic way
of constructing and fabricating all fiber asymmetric MZIs with the desired
length
differences, i.e. wavelength responses; with a very good precision.
4. Brief description of the figures
Fig 1. Shows a Mach-Zhender Interferometer in terms of two Michelson
Interferometer.
Fig 2. : Show the typical wavelength characteristics of the Mach-Zhender and
Michelson interferometer; the physical length differnce is shown as a
parameter.
Fig. 3. Shows the set up for adjusting the length of the Michleson
interfrometer using
high precision reflectometer
Fig 4. Shows the set up for adjusting the length of the Michleson
interferometer using
a broad band optical source and an optical spectrum analyzer.
5. Detailed description
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CA 02301971 2000-03-22
An optical waveguide Mach-Zhender is composed of two optical splitterlcoupler,
which
are connected to each other by two lengths of optical waveguides known as
arms. When
the arms of the MZI have diiTerent lengths they are called Asymmetric Mach-
Zhender
Interferometers or AMZI. The optical waveguides here are referred to both
optical fibers
with circular cross sections and/or planar optical waveguides with non-
circular cross
sections. When a MZI is made by optical fibers they are called all fiber MZI.
Asymmetric interferometer apparatuses are known to have periodic response as a
function of wavelength. Therefore they can be used as optical filters. It is
also known that
in particular cascaded asymmetric MZIs can act as an optical filter with good
filtering
characteristics. However to get a satisfactory wavelength resolution, the
length difference
of an asymmetric MZI has to be adjusted within a micron precision. All fiber
MZIs are
attractive because of their low insertion losses and almost polarization
independent
performance. All fiber Mach Zhender can be made by cascading two fused tapered
couplers. Referring to Fig 1 now, there is shown that each MZI can be
considered as a
cascade of two Michelson interferometers that are interconnected to each other
back to
back.
Shown in Figs 2 are the wavelength responses of the Mach-Zhender
Interferometer and
Michelson Interferometer as a function of the physical length differences of
their arms.
The wavelength response function of the interferometer, F(~,) may be written
as:
2~rnOL
F(~,) = 2 (1 + exp(> ~ ~~r~or )) , ( I )
Where n is the average refractive index of the media that light is
propagating, ~, is the
wavelength of light, and OL,~;~, is the free space optical length differences,
the total
traveling distance difference between the two propagating parts of the input
optical signal
as if they were traveling in the air. Note that for the same physical length
difference the
period of wavelength response oscillation is twice as that of for MZI. This is
because the
in the Michelson interferometer the optical length difference is twice of the
physical
length difference but it is the same as physical length difference for the
MZI. By
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CA 02301971 2000-03-22
measuring the wavelength response period, A~,, we can compute the physical
length
differences, DL, through:
~z
2~MlChelson - Mach-Zhender - - '
2n0~,
To construct a MZI with a desired length difference, we can adjust the length
of the
Michelson interferometer first and then to fuse or mechanically splice them
together to
form a MZI. In case of optical fiber coupler the length adjustment is done by
grinding
one of them while monitoring the length difference with high precision optical
reflectometer as shown in Fig 3 or the interference pattern through optical
frequency or
wavelength measurement system as shown in Fig 4. High precision optical
reflectometer
for instance can be acquired from Hewlet Packard model No. 85048.
Alternatively one
can input a broadband optical signal into the Michelson interferometer and
grind and/or
polish one arm of the Michelson interferometer while observing the wavelength
response
of the interferometer by an optical spectrum analyzer such as HP model No
709528. .
The grinding will be stopped until getting the desired wavelength response on
an optical
spectrum analyzer.
After finishing length adjustment the splicing of two optical fiber couplers
is carried out
by fusion or mechanical splicing. Several kinds of MZIs with different length
are
cascaded one by one and finally an optical multiplexer/demultiplexer is made.
Final
adjustment of the length and optical phase correction may be down by exposing
a section
of one arm of the MZI to an ultraviolet light so that we can alter the
refractive index of
that section and consequently further fine tune the optical length difference
until
achieving the satisfactory wavelength response from the MZI.
Similarly, a MZI composed of optical waveguide having optical path length
difference
shows exactly the same function as the MZI consisted of optical fiber. This
type of MZI
is very simple to fabricate compared to the conventional optical
multiplexer/demultiplexer such as interference filter, planar waveguides or
fiber Bragg
grating methods.
Claims:
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